Thermodynamics of alkali feldspar solid solutions with varying Al–Si order: atomistic simulations using a neural network potential

Abstract The thermodynamic mixing properties of alkali feldspar solid solutions between the Na and K endmembers were computed through atomistic simulations using a neural network potential. We performed combined molecular dynamics and Monte Carlo simulations in the semi-grand canonical ensemble at 800°C and considered three quenched disorder states in the Al-Si-O framework ranging from fully ordered to fully disordered. The inferred excess Gibbs energy of mixing, excess enthalpy of mixing and excess entropy of mixing are in good agreement with literature data. In particular, the notion that increasing disorder in the Al-Si-O framework correlates with increasing ideality of Na-K mixing is successfully predicted. Finally, a recently proposed short range ordering of Na and K in the alkali sublattice is observed, which may be considered as a precursor to lamellar exsolution of a more Na-rich and a more K-rich phase, a characteristic phenomenon in alkali feldspar of intermediate composition leading to perthite formation during cooling.